Non-oxido divanadium(<scp>iv</scp>) and divanadium(<scp>v</scp>) thiolate complexes with a new type of chalcogenide bridging motif

Wu, Hai‐Yin; Chang, Ya Ho; Tsai, Yi Fang; Hsu, Keng Fu; Lee, Gene Hsiang; Hsu, Hua Fen

doi:10.1039/c4dt03934c

Cited by 6 publications

(5 citation statements)

References 30 publications

(39 reference statements)

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“…The S1-V1-O1, S2-V1-O2 and S3-V1-O1 angles (Table 2) are much smaller from those in an ideal octahedron (the axis angle is 180 ), but closer to those in a trigonal antiprism (Notni et al, 2009). The bond lengths of (I) are very similar to those in previously reported non-oxide divanadium complexes, [V 2 (-E)(-2 : 2 -E 2 )(PS3) 2 ] n (E = S or Se, n = 0 or 2À, and PS3 indicates a PS3 00 derivative) (Wu et al, 2015). The VÁ Á ÁV separation in (I) is 2.8989 (14) Å , which is similar to the values seen in [V 2 (-E)(-2 : 2 -E 2 )(PS3) 2 ] n complexes (2.90-3.08 Å ).…”

Section: Resultssupporting

confidence: 85%

“…In comparison, non-oxo high-valent vanadium complexes are relatively scarce (Hsu et al, 2006) and the chemistry of these complexes has been of interest and has been investigated in our laboratory. We have utilized a tris(2sulfanidylphenyl)phosphane ligand system to obtain a class of non-oxo divanadium complexes containing chalcogenide bridges (Wu et al, 2015). In a continuation of this research, a ISSN 2053ISSN -2296 # 2016 International Union of Crystallography non-oxo divanadium(IV) complex with methanolate bridges has been synthesized and characterized, namely tetraphenylphosphonium tri--methanolato-bis({tris[2-sulfanidyl-3-(trimethylsilyl)phenyl]phosphane}vanadium(IV)) methanol disolvate, (Ph 4 P) [V 2 (-OMe) 3 (PS3 00 ) 2 ]Á2MeOH, (I).…”

Section: Introductionmentioning

confidence: 99%

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A non-oxo methanolate-bridged divanadium(IV) complex with tris(2-sulfanidylphenyl)phosphane ligands: synthesis, structural characterization and magnetic investigation

Chang

et al. 2016

Acta Crystallogr C

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Vanadium chemistry is of interest due its biological relevance and medical applications. In particular, the interactions of high-valent vanadium ions with sulfur-containing biologically important molecules, such as cysteine and glutathione, might be related to the redox conversion of vanadium in ascidians, the function of amavadin (a vanadium-containing anion) and the antidiabetic behaviour of vanadium compounds. A mechanistic understanding of these aspects is important. In an effort to investigate high-valent vanadium-sulfur chemistry, we have synthesized and characterized the non-oxo divanadium(IV) complex salt tetraphenylphosphonium tri-μ-methanolato-κ(6)O:O-bis({tris[2-sulfanidyl-3-(trimethylsilyl)phenyl]phosphane-κ(4)P,S,S',S''}vanadium(IV)) methanol disolvate, (C24H20P)[V(IV)2(μ-OCH3)3(C27H36PS3)2]·2CH3OH. Two V(IV) metal centres are bridged by three methanolate ligands, giving a C2-symmetric V2(μ-OMe)3 core structure. Each V(IV) centre adopts a monocapped trigonal antiprismatic geometry, with the P atom situated in the capping position and the three S atoms and three O atoms forming two triangular faces of the trigonal antiprism. The magnetic data indicate a paramagnetic nature of the salt, with an S = 1 spin state.

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Section: Resultssupporting

confidence: 85%

Section: Introductionmentioning

confidence: 99%

A non-oxo methanolate-bridged divanadium(IV) complex with tris(2-sulfanidylphenyl)phosphane ligands: synthesis, structural characterization and magnetic investigation

Chang

et al. 2016

Acta Crystallogr C

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“…In general, the 51 V nucleus is more deshielded in complexes with S donors than those with N/O ones due to the increasing polarizability . For instance, complexes 3 , 4 , and [V V 2(PS3″)2(μ-E2)(μ-E)] (1027 and 765 ppm for E = Se and S, respectively) have more downfield 51 V shifts than N/O ligated oxidized amavadin analogues (approximately −200 to −300 ppm). , In addition, the noninnocent nature of ligands such as catecholates also tunes 51 V nucleus in a deshielded manner . The PS3″ ligand in complexes 3 and 4 has a noninnocent character that might also give rise to low shielding.…”

Section: Resultsmentioning

confidence: 99%

Redox Interconversion of Non-Oxido Vanadium Complexes Accompanied by Acid–Base Chemistry of Thiol and Thiolate

et al. 2017

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The redox nature of the non-oxido vanadium sulfur center is associated with several biological systems such as vanadium nitrogenase, the reduction of vanadium ion in ascidians, and the function of amavadin, which is a vanadium(IV) natural product contained in Amanita mushrooms. But the related chemistry is less explored and understood compared to oxido vanadium species due to the oxophilic character of high valent vanadium ions. Herein, we present a class of non-oxido vanadium thiolate complexes, [V(PS2″S)] (1) (PS2″S = [P(CH-3-MeSi-2-S)(CH-3-MeSi-2-SH)]), [V(PS3″)(PS2″S)] (2) (PS3″ = [P(CH-3-MeSi-2-S)]), [V(PS3″)] (3), [V(PS3″)(PS2″S)] (4), and [V(PS3*)] (5a) (PS3* = [P(CH-3-Ph-2-S)]), and study their interconversion through the redox and acid-base reactions. Complex 1 consists of a six-coordinate octahedral vanadium center; complexes 2 and 4 are seven-coordinate with distorted capped trigonal prismatic geometry. Vanadium centers of 3 and 5a are both eight-coordinate; the former adopts ideal dodecahedral geometry, but the latter is better viewed as a distorted square antiprism. Complex 1 is oxidized to complex 2 and then to complex 3 with dioxygen. Each one-electron oxidation process is accompanied by the deprotonation of unbound thiol to bound thiolate. Complex 3 is also produced from complex 2 through stepwise addition of Fe(Cp)/n-BuLi, or in the reverse order. The formation of 2 from 3 is achieved in the order of adding Co(Cp) and acid or, as with the previous complex, inversely. Notably, the reduction of complex 2 to complex 1 accompanying the protonation of bound thiolate to unbound thiol only occurs with the presence of both Co(Cp) and acid, indicating a cooperative effect between the metal-centered reduction and bound thiolate protonation. The conversions among these complexes are observed with ESI-MS and UV-vis-NIR spectroscopies. The work demonstrates two-electron redox interconversion in these complexes mediated by transformations between unbound thiol and bound thiolate.

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“…The coordination environment of vanadium atoms (2I + O + 4Se) represents a distorted pentagonal bipyramid (Figure c). For vanadium cations, coordination number 7 may be found both for mononuclear vanadium complexes and a binuclear complex …”

Section: Results and Discussionmentioning

confidence: 99%

“…For vanadium cations, coordination number 7 may be found both for mononuclear vanadium complexes 4041 and a binuclear complex. 42 Complexes V 4 O(Se 2 ) 4 I 6 are aligned in columns along with direction c. In each column, the neighboring complexes alternate between their two spatial orientations due to rotation via 4 2 axis (Figure 3). Disordered I 2 molecules are situated in the space between the columns.…”

Section: ■ Experimental Sectionmentioning

confidence: 99%

Vanadium O-Centered Selenoiodide Complex: Synthesis and Structure of V₄O(Se₂)₄I₆·I₂

et al. 2021

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The first vanadium selenoiodide V 4 O(Se 2 ) 4 I 6 •I 2 was synthesized at a moderate temperature of 220 °C from V, Se, I 2 , and water. Its crystal structure (tetragonal space group P4 2 /nbc, a = 11.838(1) Å, c = 18.689(1) Åwhere the edges of the distorted tetrahedron V 4 are bridged by four diselenide (Se 2 ) 2− and two iodide ligands; four terminal iodides coordinate V atoms additionally. This type of complex is known for Ti, Nb, and Ta but is new for vanadium. Magnetic susceptibility measurements of V 4 O(Se 2 ) 4 I 6 •I 2 showed four unpaired electrons on vanadium atoms at room temperature and drop of the effective magnetic moment at cool down, presumably due to partial electron pairing. Probability of this transition to the diamagnetic state is in accord with the calculated electronic structure.

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Non-oxido divanadium(iv) and divanadium(v) thiolate complexes with a new type of chalcogenide bridging motif

Cited by 6 publications

References 30 publications

A non-oxo methanolate-bridged divanadium(IV) complex with tris(2-sulfanidylphenyl)phosphane ligands: synthesis, structural characterization and magnetic investigation

A non-oxo methanolate-bridged divanadium(IV) complex with tris(2-sulfanidylphenyl)phosphane ligands: synthesis, structural characterization and magnetic investigation

Redox Interconversion of Non-Oxido Vanadium Complexes Accompanied by Acid–Base Chemistry of Thiol and Thiolate

Vanadium O-Centered Selenoiodide Complex: Synthesis and Structure of V₄O(Se₂)₄I₆·I₂

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Non-oxido divanadium(iv) and divanadium(v) thiolate complexes with a new type of chalcogenide bridging motif

Cited by 6 publications

References 30 publications

A non-oxo methanolate-bridged divanadium(IV) complex with tris(2-sulfanidylphenyl)phosphane ligands: synthesis, structural characterization and magnetic investigation

A non-oxo methanolate-bridged divanadium(IV) complex with tris(2-sulfanidylphenyl)phosphane ligands: synthesis, structural characterization and magnetic investigation

Redox Interconversion of Non-Oxido Vanadium Complexes Accompanied by Acid–Base Chemistry of Thiol and Thiolate

Vanadium O-Centered Selenoiodide Complex: Synthesis and Structure of V4O(Se2)4I6·I2

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Vanadium O-Centered Selenoiodide Complex: Synthesis and Structure of V₄O(Se₂)₄I₆·I₂